Circuit breaker



March 15, 1949.

Filed May l, 1944 R. A. GEsELLscHAP CIRCUIT BREAKER 6 Sheets-Sheet 1 if T roRA/EK March 15, 1949- R. A. GEsl-:LLscHAP 2,464,303

CIRCU-IT BREKER Filed May l, 1944 6 Sheets-Sheet 2 March 15, 1949. R. A. GEsELLscHAP 464,303

CIRCUIT BREAKER Filed May l, 1944 6 Sheets-Sheet 3 /A/wroe: 2065er H. G fsfLLsc/mg #fromm/EK March 15, 1949. R. A. GEsELLscHAP 2,464,303

CIRCUIT BREKER 6 Sheets-Sheet 5 y Filed May 1, 1944 March 15, 1949. R. A. GEsELLsl-IAP 2:464303 C IRCUI T BREAKER Filed may 1, 1944 6 sheets-sheet e Patented Mar. 15, 1949 CIRCUIT BREAKER Robert A. Gesellschap, Brentwood, Mo., assignor to James R. Kearney Corporation, St. Louis, Mo., a' corporation of Missouri Application May 1, 1944, Serial No. 533,532

(Cl. A200--89l 8 Claims.

This invention relates generally to electrical protective devices for electrical circuits, and more specifically to oil circuit breakers, of the reclosing type, the predominant object of the invention being to provide an improved automatically operated, reclosing, oil circuit breaker which is well adapted for use with rural distribution lines to replace the single-shot and multiple-shot fused, sectionalizing devices formerly employed with such rural lines to afford protection to equipment electrically associated therewith.

For some years in the past it was the established practice in the operation of rural electrical distribution lines to provide protection for electrical equipment associated with the lines by interposing in the circuits single-shot or multipleshot fused sectionalizing devices.V However, of late years there has been a definite trend toward the replacement of such single-shot and multipleshot fused, sectionalizing devices on rural distribution lines with small, single pole, automatically operated, reclosing, oil circuit breakers so located in the circuits as to provide a considerable advantage over the use of fused protective devices.

The average rural electrical distribution system in the United 'States is made up of about 470 miles of lines which radiate from a single supply substation. These lines extend out 40, 50, and in some cases, 60 miles from the source of supply of the electrical energy, and it is difficult and uneconomical to maintain routine patrolling of long extensions, necessary when fused protective devices are employed, because of poor roads, and lack of established roads in some sections where the lines are located, this being especially' true under adverse weather conditions. Originally, many unnecessary outages were caused when single-shot, fused protective devices were used to protect equipment of rural circuits. and this led to the replacement of such single-shot devices by multiple-shot, fused protective devices. However, it was found that these repeaters, also, were inadequate to maintain proper service. operators of rural electrical distribution systems to reduce service interruptions and thereby improve service on the systems has contributed to the use of small, automatically operated, reclosing, oil circuit breakers which now are being used to a considerable extent.

While, in the use of oil circuit breakers of the types heretofore employed with rural electrical distribution lines, certain advantages were realized over the use of fused protective devices with such lines, yet, said oil circuit breakers did not function with the desired maximum efficiency inasmuch as such oil circuit breakers opened too rapidly on overloads on the lines, thus mak- The desire on the part of the ing it difcult to coordinate several circuit breakers in series, and to obtain coordination between circuit breaker and fused branches of a system. The oil circuit breaker disclosed herein is of such improved construction and arrangement that the disadvantage mentioned immediately above is completely overcome, this end being accomplished by providing the improved oil circuit breaker with time-delay mechanism which is so operable that the circuit breaker will open instantaneously on the first two openings, followed by two delayed openings before the circuit breaker locks out. As a result of this arrangement the instantaneous openings afford protection to equipment electrically associated with the distribution system and prevent conductor failures -due to arc over, while a moderate time delay on the last two openings afford better coordination between circuit breakers arranged in series, and between circuit breaker and fused branches of a system.

Fig. 1 is a front elevation of the improved circuit breaker of the present invention.

Fig. 2 is a side elevation of the circuit breaker illustrated in Fig. 1.

Fig. 3 is an enlarged vertical section of the improved circuit breaker with the bushings at the top thereof broken away.

Fig. 4 is a fragmentary rear elevation of .a portion of the circuit breaker, said circuit breaker portion being removed from the tank of the circuit breaker.

Fig. 5 is a fragmentary, vertical section showing the upper portion of the circuit breaker as same appears when viewed from the left side as the circuit breaker is illustrated in Fig. 1.

Fig. 6 is a horizontal section taken approximately on staggered line 6 6 of Fig. 5.

Fig. '7 is a fragmentary, vertical sectional view of a relay assembly which forms a part of the improved circuit breaker as will presently appear herein.

Fig. 8 is an enlarged, fragmentary, vertical section taken on line 8 8 of Fig. 3.

Fig. 9 is a fragmentary, vertical section illustrating a portion of the circuit breaker, including the operating coil and armature assembly and the associated contacts.

Fig. 10 is a fragmentary front elevation of the time-delay mechanism of the improved circuit breaker.

Fig. 11 is an enlarged, fragmentary side elevation of the time-delay mechanism illustrated in Fig. 10, with parts in section.

Fig. 12 is a fragmentary, horizontal section of the time-delay mechanism, taken on line |2--I2 of Fig. 11.

Fig. 13 is a fragmentary side elevation of the time-delay mechanism viewed from the side op- 3 posite to that illustrated in Fig. l1, with parts shown in section.

Fig. 14 is a fragmentary, sectional detail taken approximately on line |4-|4 of Fig. 12..

Fig. 15 is a fragmentary, sectional. detail taken approximately on line IS-IS of Fig. 12.

Fig. 16 is a fragmentary, sectional detail taken approximately on line I6-I6 of Fig. 12.

Fig. 17 is a fragmentary, sectional detail taken approximately on line I'I--Il of Fig. 12.

Figs. 18, 19, and 20 are fragmentary details, partly in section and partly in elevation, illusltrating parts of the time delay mechanism of the circuit breaker in different positions assumed by said parts during operation of the circuit breaker.

Fig. 21 is a fragmentary detail, partly in section and partly in elevation., showing parts of the timedelay mechanism illustrated in Fig. 16 in positions diierent from the positions assumed by said parts in that view.

Fig. 22 is a fragmentary detail similar to Fig. 16 but showing parts of the structure of Fig. i6 in changed positions.

Fig. 23 is an enlarged, fragmentary view, partly in vertical section and partly in elevation, showu ing the upper portion of the structure illustrated in Fig. 5, but with parts cf said structure in changed positions.

Fig. 24 is a fragmentary detail, partly in section 'and partly in elevation, showing an assembly of parts included in the loch-out mechanism oi the circuit breaker.

Figs. 25, 26, and 27 illustrate parts of the assembly illustrated in Fig. 24, Figs. and 2d illustrating parts in perspective, and Fig. 2? showing asso ciated parts in section.

Figs. 28, 29, and illustrate another' part of the assembly shown in Fig. 2d, Fig. 23 illustrating the part in side elevation, Fig. 29 illustrating said part in front elevation, and Fig. 30 being a top plan view of the part.

Fig. 31 is a diagrammatical view illustrating the wiring of the improved circuit brealrer.

In the drawings, wherein is shown for purposes oi' illustration merely, one embodiment of the invention, A designates in Figs. i and 2 the irnproveol circuit breaker generally. The circuit breaker A includes a tank ll comprising a body portion 2, of cylindrical or other suitable shape, which is closed at its bottom by a bottom wall that is welded or otherwise secured in place (Fig. 3) .Arranged within the tanir` l, in contact with the side wall and the bottom wall thereof, is a lining member [i which is formed of fiber or other material that is a good electrical insulator and which is not affected by contact therewith of the oil C within the tank. The body portion 2 of the tank Il is provided at its upper end with an annular, outwardly projected iiange 5, and the upper portion of the body portion of the tank 2 is closed by a head d which is secured in place by suitable clamping devices 'l spaced circum ierentially of the tank (Figs. l and 2), said clamping devices being pivoted to members d secured to the body portion of the tank and being arranged to clampingly engage an annular, outwardly projected flange d formed on the head or the tank.

Formed on the top wall of the head of the tank I, and projected downwardly therefrom, is

a plurality oi bosses id, each having formed there.

in a tapped opening that is open at the bottom of the boss. The tapped openings of the bosses have screwed thereinto the serein/threaded upper end portions of vertically disposed rods lll, said rods being embraced by tubular spacers I2 formed of ber or other suitable electrical insulating material.y The spacers contact at their upper-enii$i with the bottom faces of the bosseslll and at their lower ends with the top face of a. horizontally disposed plate I3, which likewise is formed of iiber or other suitable electrical insulating material,-the plate I3 thereby being maintained in its proper spaced relation with respect to the tank head 6. The rods II extend through openings formed through the plate I3 and have screwthreaded lower end portions located beneath said plate (Fig. 5).

The plate I3 is secured in place by tubular spacers I4 which are internally screwthreaded at their upper ends and are screwed onto the screwthreaded, lower end portions of the rods Il, the plate i3 being clamped between the lower ends of the spacers I2 and the upper ends of the spacers i4. Also, a second horizontally disposed plate I5 is arranged in downward spaced relation with respect to the horizontal plate I3. rihe horizontal plate l5 is maintained in position by being secured to the lower end portions of the spacers it, bolts lt being employed which pass through openings formed through said plate I5 and the upper screwthreaded portions of the bolts being screwthreadedly received within the internally screwthreaded, lower portions of the spacers I4. The spacers lil and the horizontal plate I5 are formed oi ber or other suitable electrical insulating material,

Supported between the horizontal plates i3 and l5 is an operating coil assembly ii which com-= prises a coil Iii having a tubular core i9 through which operates an armature 20 (Fig. 9). The armature 2t is slidably supported by a rod 20a which has secured thereto at the lower end thereof a member 2l provided with a horizontally dis posed arm portion at the opposite ends of which downwardly projected contacts 22 are mounted.

In order to secure the contacts 22 to the horil. zcntal arm portion of the member 2l said con` tacts are provided with portions 22a of reduced diameter that extend through openings iormed through the opposite end portions of said arm portion, and nuts 22o are applied to the upper portions of these reduced portions to clamp the contacts in place. The coil l@ rests upon the horizontal plate i5, as is shown to'good advantage in Fig. 9, and the lower portion or the tubular core extends through an opening formed through said plate l5 and projects slightly below same, the outer face of the core contacting ciosely with the wall of the opening formed through the plate l5. The rod 2da is provided with a screw/threaded portion 2th on which a pair or nuts 2de are mounted and which serve a purpose to be herein after set forth.

Secured to the horizontal plate l5 at the bottom face thereof is a member 25S which is shaped to provide a cavity 2li into which the lower end portion of the core l@ of the coil assembly projects slightly. rhis cavity 2@ is of such shape and diameter that the upper portion 25 of the con tact-supporting member M may pass into said cavity, when the armature approaches the limit of its upward movement, so as to function as a plunger therein which acts against the oil in the cavity to provide a hydraulic stop for the armature. Arranged in downward spaced relation with `respect to the horizontal plate i5 is still another horizontal plate, a lower horizontal plate 26, which is formed of ber or other suitable insulating material. The lower horizontal plate 26 is connected to the intermediate horizontal plate I5 by tubular spacers 21, formed of ber or other suitable insulating material, said spacers being internally-screwthreaded at their opposite ends, and bolts 28 being extended through openings formed through the plates I5 and 26 and screwed into said screwthreaded end portions of said spacers so as to anchor the lower' horizontal plate 26 in place.

Supported between the horizontal plates I5 and 26 is a cylindrical member 29 which is formed of liber or other suitable insulating material. The cylindrical member 29 is closed at its top by the horizontal plate I 5 and at its bottom by the horizontal plate 26 to provide an arc-interrupting chamber, the wall of said cylindrical member having a vent opening 30 formed therethrough (Fig. 3). Disposed Within the chamber provided by the cylindrical member 29, at the bottom thereof, is a pair of stationary contacts 3| and 3l' into and out of electrical contact with which the movable, armature-supported contacts 22 are adapted to move.

The stationary contact 3l is shown to good advantage in Fig. 8 wherein the illustrated contact is shown as comprising a U-shaped portion 32 which is mounted at the upper end of a stud 33 that extends through openings formed through a ilat sheet 34, which provides the bottom wall of the interrupting chamber', and through the lower horizontal plate 26. The lower portion of the stud of the stationary contact 3| is screwthreaded and a nut and washer assembly 35 is associated with said screwthreaded stud portion so that the washers closely engage the bottom face of the horizontal plate 26 and a shoulder 33' at the upper portion of the stud contacts firmly with the top face of the flat sheet 34. The U- shaped portions 32 of the stationary contact 3| has riveted, or otherwise fixed, to the opposed, upturned legs thereof, a pair of opposed contact elements 36 which are flared upwardly and outwardly so as to facilitate passage of the movable contact 22 therebetween, the U-shaped portion of the stationary contact being suiliciently resilient to permit the legs of said U-shaped portions to spread slightly when the movable contact 22 moves between the contact elements 36. Additionally, the studs 33 of the stationary contacts 3| and 3I have mounted on the lower screwthreaded portions thereof lower nuts 31 which serve to mechanically and electrically connect to the stationary contacts the electrical conductors leading thereto, said wires being clamped between the lower nuts 31 and the nuts of the nut and washer assemblies 35.

The improved circuit breaker disclosed herein includes a small, series relay 38 for controlling the operation of the circuit breaker. The relay 33, which is shown to good advantage in Fig. '1, com-- prises a coil 39 having a cylindrical core 40 extended therethrough and projected above and below same. The core 40 is externally screwthreaded at its opposite ends, the upper screwthreaded end portion of said core having screwthreadedly mounted thereon a cap 4I whose lower portion is disposed in an opening formed through the horizontal plate I3, and said cap being provided with an annular ange 4I which contacts with the top face of said horizontal plate I3. The upper portion of the cap provides an upwardly projected guide 42 which serves a function to be hereinafter referred to. Arranged in embracing relation with respect to the portion of the core extended between the top of the coil 39 and the lower face of the horizontal plate I3 is `a cylindrical spacer 43. The lower, externally screwthreaded portion of the core 40 has screwthreadedly mounted thereon a cap 44 through the bottom wall of which an aperture is formed.

Disposed within the core 40 of the relay 38 is an armature 45 which is movable longitudinally of said core during operation of the relay, said armature 45, of course, being formed of electrical conducting material. The armature 45 is generally of tubular form and is internally screwthreaded at its upper end, and is provided with a wall at its lower end through which a centrally located opening is formed. The internally screw threaded upper portion of the armature 45 receives an externally screwthreaded portion 46 of a rod 46 whichextends through a portion of the core of the relay and outwardly beyond the cap 4I associated therewith. The rod 46 includes a portion 41 of relatively large diameter which is located immediately above the screwthreaded portion 46', and extended upwardly from this portion 41 is a rod portion 48 of reduced diameter which is bifurcated at its outer end and is provided with vertical slots 49 in the spaced legs of said bifurcated portion. The relay 38 includes also a rod 50 which is independent of the rod 46 and is disposed in part within the armature 45, said rod 5U being provided with an enlarged head 50 at its upper end and being extended through the opening in the bottom wall of the armature and through the similar opening formed through the bottom wall of the cap 44. The rod 50 has secured to its lower end portion an electrical contact 5I, and interposed between the lower wall of the cap 44 and the top portion of the contact 5I is a coil spring 52 that embraces the rod 5U and tends to move the rod 5D and its contact 5I in a downward direction.

The relay 38 is so arranged that the rod 50 extends through an opening 53 formed through the'horizontal plate I5, and supported by said horizontal plate I5 is a bracket member 54 which has xed thereto an electrical contact member 55 into and out of electrical contact with which the contact member 5I is adapted to move in response to operation of the relay 38. The bracket member 54 is formed of electrical conducting material and it is secured to the horizontal plate I5 by a bolt 56, which also is formed of electrical conducting material, said bolt serving, additionally, to secure to the horizontal plate I5 an element 51 formed of electrical conducting material, the bolt 56 acting to electrically con- I nect the bracket 54 and the element 51. Secured to the element 51 is a vertically disposed strip of suitable electrical insulating material 58, through which is extended a bolt 59 formed of electrical conducting material, the upper portion of the element 51 being oiset slightly with respect to the lower portion thereof and this offset element portion being spaced from the head of the bolt 59 so as to provide a coil-protecting gap 60 therebetween.

Mounted on the head 6 of the tank I is a pair of bushings 6I and 62 which are suitably secured to said tank head. At their upper portions the bushings 6I and 62 are provided with suitable terminals 63 to which are connected incoming and 'outgoing conductors /whichaserve/togiransmit electrical energy tothe circuit breaker A. Also, suitably connected to the terminals of the bushings 6I and 62 are conductors which are electrically associated with various parts of the circuit breaker. The latter conductors are illustrated diagrammatically in Fig. 31 wherein is shown a conductor B which leads from they terminal 63 of the bushing 6l to the coil 39 of the relay 38. Leading from the coil of the relay 33 to the coil I8 of the operatingcoil assembly Il is a conductor C, and leading from said coil I8 is a conductor D which is connected to the stationary contact 3i of the circuit breaker. Additionally, the conductor D which leads from the coil i8 of the operating coil assembly il has connected thereto a conductor E which connects the stationary contact 55 of the relay 38 to said conductor D and hence to the stationary contact 3| to which the conductor D is connected. The wiring illustrated diagrammatically in Fig. 31 includes also a conductor F which leads from the stationary contact 3l' of the circuit breaker to the terminal 63 of the bushing @52. Also, a pair of conductors G and H form parts of the Wiring arrangement to the circuit breaker, the conductor G leading from the point where the conductor B connects into the coil 39 or" the relay 38 to the bolt 59, and the conductor H leading from the element 51 associated with the relay Sii to the point Where the conductor D connects into the coil I8 of the operating coil assembly lil. The gap 6D, previously mentioned herein, is arranged in the current path provided by the conductors G and H. A conductor connects the movable contact 5I of the relay 38 to the conductor C.

In order to protect the circuit-breaker from surges due to lightning or other causes, surge arrester assemblies are associated with the bushings Si and S2. These arrester assemblies coinprise arms t4, formed of electrical conductive material, which are mechanically and electrically connected to the terminals @Si or" said bushings bi and 62, and upstanding structures supported by the head 6 or" the tank which include portions formed of electrical conductive material that are electrically connected to said tank head. rI'he arms t4 and the heads 655i' of the upstanding structures 65 are spaced apart to provide gaps @t and the tank i is grounded, hence adequate surge protection will be afforded the circuit breaker in an obvious manner.

As previously stated herein, the predominant feature of the present invention is that the circuit breaker is adapted, on a sustained fault to open four times in succession and then. lock out, the circuit breaker remaining so locked out until the fault has been removed from the line and the circuit breaker is reclosed manually. The first two openings of the circuit breaker are in stantaneous, and are followed by a third and a fourth opening which are retarded by an inertiatype time delay mechanism. The time delay mechanism will now be described.

The time delay mechanism o the improved circuit breaker A includes a supporting frame comprising a vertically disposed bracket @il provided with a horizontal riange til at its upper end which is secured by suitable iastening devices titi to a lower face portion of the head t of the tank l at a side of said tank head (Fig. 5). Projected from the bracket is an ear it@ to which is attached by a suitable securing element t9 a vertically disposed plate lli). Associated with said plate 'l0 is a similar plate lli, said plates il@ and il being spaced apart transversely of the circuit breaker, as is shown to good advantage in Fig. i2. interposed between upper portions of the plates 7l) and ll, and extended outwardly beyond same, is a horizontally arranged bar iii, said bar being secured to said plates by suitable fastening ele- A,ments 12', and the outer extended end portion of said bar 12 being secured by a fastening element i3 to an elongated boss 14 which is projected downwardly fromthe top wall of the tank head 6. rThe fastening element 69 serves also to attach the plate 'H to the ear 69 of the bracket 61, said fastening element 69' being in the form of an elongated bolt which passes through both of the plates 10 and 1I and having a nut associated therewith, and a tubular spacer 15, which embraces the shank of said bolt, being interposed between said plates 10 and 'H (Fig. 12).

The plates il) and il support for rotation a horizontally disposed shaft 'I6 on which is ilxedly mounted for rotation therewith a ratchet wheel ill. The ratchet wheel has associated therewith a pawl 18, which is shaped as is shown to good advantage in Figs. 18, 19, and 20, said pawl comprising an elongated member having an extension 'i8' shaped and arranged to engage the teeth of the ratchet wheel ll'i. Ilihe pawl is pivotally attached at one oi its ends, by a pivot member element i9a, to an arm i9' of a member "t9, said member 'i9 including a hub portion 8U which is supported by the shaft i6 for movement with respect thereto, and the arm i9 being extended outwardly from said hub portion, the hub portion .800i the member i9 having extended therefrom also a second arm Si.

Located above and slightly to a side of the shaft it is a shaft 82, which is supported ior rotary motion by portions 211, 32h. and 82e of the head t of the tank l (Fig. 6). The shaft 82 is generally of circular cross-seotional shape but is provided with a fiat portion 83, shown to good advantage in Figs. 2d and 27, which extends throughout the major portion of 'the length of the shaft (Fig. 25). The shaft 82 has mounted thereon an arm il@ which is provided with a hub portion 35 at its inner end, and a ring or eye 85 at its outer end, the hub portion having a bore formed therethrough which corresponds in shape to the cross-sectional shape of the portion of the shaft 32 having the attened portion 83, and the hub portion of the arm being mounted on a part of the flattened portion oi the shaft so that it will rotate with the shaft. Mounted also on the shaft S32 is a lever structure till (Fig. 6) which comprises a hub portion tti through which the shaft 82 extends and a pair of substantially par allel arms @il extended from said hub portion, said parallel arms being joined by a transverse web @il adjacent to their outer ends. 'The hub portion t8 of the lever structure 8i is mounted on a part of the flattened portion of the shaft 82 but the bore through said hub portion is completely circular, and therefore said hub portion may oscillate about said iattened shaft portion without restraint because of the at face thereoi.

Additionally, the shaft t2 has mounted on the iattened portion thereof an element 9i (Figs. 24 and 26) which comprises a huh portion havs ing a bore shaped in accordance with the cross= sectional shape of said shaft portion so that said element will rotate with the shaft 82. The outer surface of the hub portion o the element Si is circular and said hub portion has extended outwardly therefrom an ear et. Supported by the element 9i is a member 93 which includes a hub portion that embraces the hub portion of said element 9i (see Fig. 24) with the race of the bore oi the hub of the member 93 in sliding contact Vextends from the hub portion thereof, and an arm structure 98 which likewise extends from said hub portion and is spaced from the arm 95, longitudinally of the hub portion of said member 88. The arm structure 98 is 'provided with an ear 81 to which a short lever 98 is pivoted by the pivot element 99, 'the opposite, or outer, end of said short lever having pivotally attached thereto a link which is pivotally connected at its opposite end to the ear 92 ofthe element 9| (Fig. 24). The arm structure includes a latch-engaging face I0|, which serves a purpose to be hereinafter set forth, and a horizontally disposed abutment element |02 which performs a function to be hereinafter described. Additionally, the outer end of the arm 95 of the member 93 has attached thereto an end portion of a coil spring |08 whose opposite end is connected to an anchoring element |04 arranged in screwthreaded engagement with a part |04 of the head 6 of the tank I.

' Pivotally connected to the lever structure 81 is a pair of spaced, parallel arms |05 which extend downwardly from said lever structure and are pivotally connected at their lower ends by a pivot element |08 to the upper end portion of the rod 20a of the operating coil assembly I1 (Fig. 9). The upper end portions of the spaced, parallel arms are arranged at opposite sides of the outer end portion of oneof the arms 89 of the lever structure 81v (see Fig. 6) and a pivot element |01 which is supported by the outer end portions of both of the arms 89 of the lever structure 81 serves to pivotally attach said upper end 10 and the shaft 16 on which it is iixedly mounted. However, it is to be noted that When the roller I I3 of the pawl 18 is in contact with the cam face III ofthe plate I|0 the extension 18 of the pawl is raised out of contact with the teeth of the ratchet wheel 11, as is shown in Fig. 19, and that the extension of the pawl is likewise moved out of engagement with the teeth of ratchet wheel when the roller of the pawl contacts with the cam face |I2. In other words, the extension 18' of the pawl 18 engages the teeth of the ratchet wheel-11 only during that portion of the movement of the pawl about the shaft 16 when the roller |I3 of the pawl is traveling between the portions of the spaced, parallel arms |05 to the lever structure 81. Also, the pivot element |01 pivotally connects the upper end portion of an arm |08 to the lever structure 81, this arm |08 including a sleeve portion |08 at its upper end which embraces the pivot element |01 in interposed relation with respect to one of the spaced arms |05 and one of the arms 89 of the lever struc ture (Fig. 6). At its lower end the arm` |08 is pivotally connected by a pivot element |09v to .the outer end portion of the arm 8|V of the mem-` ber 19.

The shaft 16, previously mentioned herein,v

extends through a vertically disposed plate I0 which is supported by the bracket 61 (Figs. 11 and 12). At its top edge the plate IIIl is provided with a curved cam face III, and at its lower, forward portion said plate is provided with arcor'ner-like portion ||2 which provides another cam face. The pawl 18 is provided at its free end with a roller I I3 (Figs. 18, 19, and 20) which at times during the operation of the circuit breaker is adapted to ride on the cam face I and at other times is adapted to contact with the cam face ||2, there being a coil spring II'4, attached ,at one of its ends to the free end of the pawl and attached at its opposite end to a suitable anchoring element II 5 fixed to the hub portion of the member 19, which tends to draw the free end portion of the pawl 18 inwardly toward the shaft 16. It will hereinafter appear that the pawl 18 moves with the member 19 about the shaft 16 and that during a portion of such movement the extension 18' of said pawl engages the teeth of the ratchet wheel 11 to rotate the ratchet wheel forward edge of the cam face III' and the cam face I|2.

By referring to Fig. 12 it will be noted that a housing II6 is provided which is secured to the plate 1|. This housing, which is rShown to good advantage in Fig. 17, is provided with a torsional spring ||1 which is enclosed within the housing. As is shown in Fig, 17 the inner end portion of the torsional spring is anchored to the shaft 16 at |I`1a and the opposite end portion of said torsional spring is secured to the housing IIS at II1b. The housing |I6 is closed at its front by a plate II8 as shown in Fig. 12, and this plate is omitted in Fig. 17. From the foregoing it is obvious that While the shaft 16 is being rotated by coaction between the pawl 18 and the ratchet wheel 11 the torsional spring will be wound to increase the tension thereof, and that when the extension of the pawl is disengaged from the teeth of said ratchet wheel 11 by contact of the roller |.I3 of said pawl with the cam face II2, the torsional coil spring will tend to rotate the shaft 16 in the reverse direction to the direction of rotation imparted to said shaft by the pawl 18.

Fixedly mounted on the shaft 16 for rotation therewith is a gear wheel II9, and arranged in mesh with said gear wheel is a pinion |20. The pinion |20 is ixedy mounted on a shaft |2| which is supported for rotation by the spaced plates 10 and 1|, previously mentioned herein, and at its opposite end said shaft |2| has flxedly mounted thereon a toothed escapement wheel I 22 with which is associated an escapement pawl |23 (Fig. 16). The escapementfpawl |23 is fixedly mounted on a shaft |24 which is supported by .the spaced plates 10 and 1I for slight oscillatory movement with respect thereto, and also xedly mounted on said shaft |24 is a Weight |25 (Fig. 17) which is disposed between said spaced plates 10 and 1I. It is obvious that as the shaft 16 is rotated by coaction between the pawl 18 and the ratchet wheel 11, the gear wheel I|9 will be likewise rotated, and because of the operation of the escapement mechanism made up of the wheel |22 and the pawl |23, the speed of rotation of said shaft 16 will be limited. Additionally, with regard to the gear wheel I I9, it is pointed out that a pin |28 is fixed to said gear wheel and projects therefrom (Fig. 12). Also, the plate I'IU supports a screwthreaded element |21 which serves as an abutment with which the pin |26 shaft 16, and the high spot of the cam is adapted to contact with the lower arm portion itt' of a latch |29, said latch being attached by a pivot to an arm I3! for pivotal movement about said pivot |30. The latch |29 i-s adapted to engagethe latch face IIlI of the arm structure 9S, as is shown in Fig. 24, and when said latch so engages said latch face the member @t is held in the position shown in Fig. 24. When so positioned the coil-spring |03 tends to move the arm 95 of the member S3 to the left, but, because the latch |29 engages the latch face iti of the arm structure 36 of said member t5, movement of the member 93 is prevented. However, when the high spot i253' oi the cam i2@ engages and moves the lower arm portion of the latch H29, the upper portion of said latch is disengaged from the latch face lili of the arm structure 9b, where=l upon the coil spring |03 moves the member @il to the position in which it is shown in Fig. 23. When the member 93 is moved by the coil spring |83 as described, the element til and the shaft 82 are rotated by the link it@ so as to move the arm til to its lowered position as shown in Fig. 23. Also. movement of the member from the position shown in Fig. 2e to the position shown in Fig. 23 upon disengagement oi the latch ill@ from the latch face iti of the arm structure oi said member t3, will result 'in the abutment element iti. of the member engaging beneath a portion oi the lever structure il so as to raise said lever structure to the position in which it is shown in rige/2B, whereby the contacts 22 will be raised upwardly and will be disengaged from the stationary contacts 3i and di' to loch out the circuit breaker.

By referring lto Fig. l2 it will be noted that a pair oi plates H32 and 632' are supported by the plate "ii in spaced relation with respect thereto, the plate |32 being in closely spaced relation with respect to said plate "it, while the plate ist' is disposed in wider spaced relation with respect to the plate 332. The plates i132 and i322 are secured to the plate 'il by suitable bolts i133 which gagement with the teeth of the ratchet wheel |35, one end portion of said coil spring being attached to the pawl and the opposite end thereof being attached to the arm IIB. As has been previously stated herein, the upper portion of` the rod portion 48 of the relay 38 is bifurcated and the spaced parts of said bifurcated portion are provided with the vertically extended slots t9. These slots have extended therethrough the lower portion of a link i, said link being U- shaped as is shown in Fig. l0, and the upper portion of said linlr being extended through an opening formed through a portion of the arm Mit (see Fig. 2l). Also, the link |56 includes a dat strip of material ibi (Fig. lill which is provided with apertures through which outer parts of the upper and lower portions oi? the U-shaped part of the linlr entend, cotter pins being provided which retain the at strip of material in its assembled relation with respect to the il-shaped part of the iinls.

The ratchet wheel i3d has associated with it an arm ifi-52 (Figs. le, l5, ld, and 2i) which is supported for pivotal movement by a portion of the shaft tilt. .a portion of the arm Q52 is disposed immediately -adjacent to the ratchet wheel E35 and in contact with a side face thereof and mounted thereon for rotation therewith a cam are embraced by spacers that are disposed bein mesh with said gear wheel ill is a pinion it@ which is mounted cna shaft Mit. Also, mounted on the shaft M0 is a gear wheel tdi which meshes with a pinion |52 that is mounted on the shaft |33, and rotatable with said pinion M2 is a gear wheel |43 which meshes with a pinion idd that is mounted on the shaft itt. The shaft it@ also supports a fly wheel |45 that is rotatable with thev pinion IM.

By' referring particularly to Figs. li, l5, and 2l, it will be noted that a pawl ltd is provided whose outer free end is adapted to engage the teeth of the ratchet wheel |35, as is shown in Fig. 2li. This' pawl |46 is attached by a pivot it to a portion |48' of an arm B4B which is supported by the shaft |34 for oscillatory movement with respect thereto, a portion of said arm being interposed between the ratchet wheel itil and the gear wheel |36 and this yarm portion being pro=s vided with an opening through, which the shaft |34 passes. The pawl |46 has associated therewith a coil spring |49 (Fig. l5) which tends to draw. the outer, free end of the pawl into entt, and this cani engages a pin |55 which is fixed to the end portion of the tail portion i152' of the 'arm E52 (Figs. it, l5, i6, and 2l).

The arm |152 is provided with a coil spring H55 which tends to move said arm to the position shown in Fig# 2l, where the cam face E53 of the yarm '952 is located inwardly slightly of the bases of the teeth of the ratchet wheel 35, and when the arm |52 is so positioned the pawl M6 may engage .the teeth or the ratchet wheel for imparting rotary movement to said ratchet wheei. However, the cam H56 is provided with a high portion, and during'certain phases of the operation of the circuit breaker said high portion of the cam will depress the outer end of the tail portion |52 of the arm |52 so as to elevate the cam face its of the arm |52 to the position in which it is shown in Figs. le and 15. The pawl |88 overlaps the cam face |53 of the arm |52, and, therefore, when said cam face is elevated as shown in Figs. 1d and l5, the pawl is prevented from en gaging the teeth of the ratchet wheel |35 and will slide along the cam face |53 of the arm |52 during movement of the pawl about the shaft i3d without imparting rotary movement to the ratchet wheel.

The escapement pawl |23 has associated with it la locking element i (Fig. 16) which is supported for pivotal movement by apivot |58. said locking element being provided with an extension |59 having an inclined face |59' which is adapted to engage a correspondingly inclined face |60 formed on the escapement pawl |23 to prevent actuation of said escapement pawl. The locking element |57 is provided with a coil spring ESI which tends to move said locking element to the position in which it is shown in Fig. 16, where 13 the inclined face |69' of the locking element engages the inclined face |80 of the escapement pawl |23. The locking element |51 includes an inclined vportion |51a, and a lower, substantially vertical portion |5112, said vertical portion |51b being provided at its lower end with a horizontally disposed flange |62 (Fig. 10). noted from Fig. 10 th-at the horizontal flange |62 of the locking element |51 is disposed beneath and in vertical alinement with an extension |50 of the link |50 which connects the pawl arm |48 to the rod portion 48 of the relay 38. As a result of this situation the extension |50' of the link |60 engages the fiange |62 of the locking element, when the link is in its lowered position, so as to elevate the end portion |59 of said locking element out of engagement with the escapement pawl |23. However, as the relay 38 is actuated to cause the rod portion 48 to move upwardly,

the link |50 likewise moves upwardly, thereby disengaging the link extension |50 from the flange of the locking element and permitting the coll spring |6| to move the locking element to a It will be lll position where its portion |59 engages and locks v the escapement pawl |23, as is shown in Fig. 16.

In describing the operation of the improved circuit breaker it is pointed out that when the contacts 5| Iand 55 of the relay 38 are in their normal contacting relation a shunt path is provided across the terminals of the main operating coil 1, and that very little current passes through the operating coil until an overload occurs. Upon occurrence of an overload the armature 45 and the rod 46 of the relay 38 move upwardly with respect to the rod 50, the top face of the bottom wall of the armature eventually engaging the lower face of the enlarged head 50' of the rod 50 so as to cause the rod to move upwardly with the armature and rod and thereby move the contact 5| upwardly away from the contact 55, against the force of the coil spring 52, so as to'interrupt the shunt path across the terminals of the operating coil I1. Upon separation of the relay contacts 5| and 55, as described, the overload current is diverted through l the operating coil |1, thereby causing the armature 20 of the operating coil to move upwardly with respect to the rod 20a at high speed. During such upward movement of the armature 20 cf the operating coil the upper end thereof strikes end of the lever structure 81 and said lever structure swings about the shaft 82. Also, swinging movement of the outer portion of the lever structure 81 is transmitted to the arm 8| of the member 18 by the arm |08 so as to rotate the hub portion of said member 19 about the shaft 16 and thereby cause the pawl 18 to be moved in a clockwise direction by the arm 19 of the member 19 about the ratchet wheel 11. The circuit breaker is locked out only after four opening operations *91nd, therefore, as the circuit breaker recloses A after each of the first three opening operations the pawl 18 will engage the teeth of the ratchet wheel 11 and rotate the shaft 16 in. a counter clockwise direction during such reclosing operations of the circuit breaker. Such rotation of `be a sustained fault.

the shaft 18 during reclosing operations of the circuit breaker will bring into operation the escapement mechanism made up of the escapement wheel |22, the escapement pawl |23, and the pawl weight |25 with the result that downward or reclosing movement of the contacts 22 will be retarded so as to give the fault ani opportunity to clear. However, as the contacts 22 approach the stationary contacts 3| and 3|' the roller ||3 at the outer, free end of the pawl 1,8 engages the cam face ||2 (Figs. 18, 19, and 20) so as to d'isengage the pawl from the teeth of the ratchet wheel 11, whereupon the contacts 22 move rapidly into electrical contact with said stationary contacts 3| and 3|.

As has been previously stated herein the flrst and second opening operations of each series of four opening operations of the circuit breaker are rapid, while the third and fourth opening operations of each such series of opening operations are relatively slow. The speed of the opening operations is controlled by the arm |52 (Figs. 14, 15, and 21) whose pin |55 is engaged by the cam |54 which is fixed to the shaft 16. On the rsttwo opening operations` of any series of opening operations of the circuit breaker the cam face H53 of the arm |52 is held outwardly of the teeth of the ratchet wheel |35 by the cam |54, as is shown in Figs. 14 and 15, and therefore the free end of the pawl |46 will ride along the cam face |53 of said arm |52 and will thereby be prevented from engaging the teeth of the ratchet wheel |35. However, as the cam |54 rotates with the shaft 16 during reclosing operations of the circuit breaker, said cam 54 will reach a position just prior to the third and fourth opening operations of the circuit breaker, where the coil spring |56 may move the arm |52 to a position where its cam face |53 is located inwardly of the bases of the teeth of the ratchet wheel |35, as is shown in Fig, 21, thus permitting the free end ofthe pawl |46 to engage the teeth of said ratchet wheel. Therefore, the first two operations of the relay 38 of each series of four opening operationsof the circuit breaker will be rapid because the vspeed of operation of said relay is in no manner retarded, the pawl |46 merely sliding along the smooth cam face |53 of the arm |52. However, during the third and fourth opening operations of any series of opening operations of the circuit breaker, the pawl |46 engages the teeth of the ratchet wheel 35, and because an additional buidenis imposed on the relay of rotating the ratchet wheel |35, and the gear wheel, pinion, and fly wheel assembly associated therewith, the speed of operation of the relay his substantially retarded and more time is required to separate the relay contacts 5| and 55.

As has been previously stated all of the reclosing operations of the circuit breaker are retarded by the escapement mechanism, while the last two opening operations of each related series of openving operations of the circuit breaker are likewise retarded as is explained immediately above. These time delays are provided to permit sufficient time for the fault to clear, if it should not In the event the fault should clear before the circuit breaker has gone through its complete cycle' of four opening operations, the circuit breaker will, of course, remain in its reclosed position, during which the roller I3 of the pawl 18 is in contact with the cam face ||2 and said pawl is disengaged from the teeth of the ratchet wheel 1'1.v The torsional spring |1 (Fig. 17) may then restore the shaft 16 and the torsional spring may not rotate the shaft 'l5 ina clockwise direction to restore said shaft to its initial position. it is only when the circuit breaker remains closed on clearance of the fault,

i or when the circuit breaker is locked. out that the torsional spring ill iunctions'to restore the shaft l@ to its normal, initial position.

It is to be noted that when the relay is being actuatedP that is, while the rod it is moving up vlerdly from its normal lowered position and is returning to such lowered position, the escape= ment mechanism provided by the escapenient Wheel i522 and the escapernent pawl i2@ is locked the inciting element itil. This arrangement prevents retrograde motion being imparted to the l@ by 'the paivl lil as its extension lil rides over the teeth oi the ratchet wheel 'il during opening movement of the circuit breaker. @bvioinly, when the circuit breaker starts a reclosing operation the rod d@ of the relay will have reached its lowermost position and the locking element itil? will have been raised out oi engage ment with the escapernent pawl i523 to release the shaft lo rior rotation.

lin the event that the circuit breaker goes through-its complete cycle of operations without the iault being cleared, the circuit breaker locks out after the fourth opening operation. This result is brought about by the high spot idd oi the cam it@ on the shaft Lremoving the lower arm portion i255 of the latch i2@ so as to dis engage said latch from the latch face lili oi the arm structure tit, thereby freeing the member Q3 for such movement by the spring tilt as will cause the abutment lili of said member to engage beneath a portion of the lever structure til and raise said lever structure, as shown in Fig. 23, so' as to elevate the main contacts 522 of the circuit breaker out of contact with the associated stas tionary contacts ill and iii. When the circuit reaker locks out, the arm til moves to the position in which it is shown in Fig. 23, and this is the only time when said arm moves to such position, as on all opening operations other than the fourth opening operation of a related series of opening operations the hub portion or the lever structure merely oscillates about the shaft 82 without imparting rotary movement thereto.

When it is desired to close the circuit breaker after it has been locked out, a suitable switch stick is employed for moving the outer end portion of the arm 8d upwardly by engaging the linger of the stick with the eye of said arm. rThis operation rotates the shaft b2 and the element Eli associated with said shaft, the ear 92 of said element ill engaging an end wall of the arcuate recess @t and rotating the member @3 about the shaft t2 to tension the coil spring iili and cause the latch face lill oi said member 93 to be engaged by the latch 52e. lt is obvious that the circuit breaker cannot be closed in on a fault and held closed by the arm 84, because the various mechanisms which cause the opening and reclosing operations of the circuit breaker to be performed are operable independently of said arm 84. If it be desired to actuate the circuit breaker manually to the locked out position, the arm 8d is pulled down wardly witnthe aid of a switch stick. This operation rotates the shaft 82 and its associated element 2l (Fig. as) in a clockwise direction thereby causing such pivotal movement to be imparted to the lever 98 by the link |00 as will cause the tail portion 93' of said lever 98 to contact with and disengage the latch |29 from the latch face lili or the arm structure 96, thereby permitting the coil spring H13 to move the circuit breaker to its locked out position as has been previously explained herein.

While the improved circuit breaker disclosed herein is described as being operable to obtain two quick opening operations and two delayed opening operations, it is to be understood that the invention is not limited to such precise sequence oi operations, as the circuit breaker may be arranged to function so as to provide any desired combination of quick and delayed opening operations witliout departing from the spirit of the invention.

l claim: l

ll.. in automatic reclosing circuit breaker como prising a plurality of main contacts, an operaia ing coil having terminals and adapted when energized to separate said main contacts, a rela-y coil,contacts associated with said relay coil which when closed complete a shunt path across the terminals of said operating coil and which are adapted to be separated when said relay coil is energized by an overload current to interrupt said shunt path and thereby cause the overload current to be diverted through said operating coil to separate said main contacts, means for locking .said main contacts in open relation after a predetermined nurnber oi opening and reclosing operations of said main contacts, means operable by said relay coil for delaying opening of said shunt contacts on energization of said relay coil by an overload current, and means for normally rendering said delaying means inoperative and operated by said locking means to render said delaying means operative.

2. An automatic reclosing circuit breaker comprising a plurality of main contacts, an operating coll having terminals and adapted when energized to separate said main contacts, a relay coil, contacts associated with said relay coil which when closed complete a shunt path across the terminals of said operating coil and which are adapted to be separated. when said relay coll is energized by an overload current to interrupt said shunt path and thereby cause the overload current to be diverted through said operating coil to separate said main contacts, means for locking said main contacts in open relation after a predetermined number of opening and reclosing operations of said main contacts, means operable by said relay coil including an inertia type timedelay mechanism for delaying opening of said shunt contacts on energization of said relay coil by an overload current, and means for normally rendering said delaying means inoperative and operated by said locking means to render said delaying means operative. v

3. An automatic reclosing circuit breaker comprising a plurality of main contacts, an operating coll having terminals and adapted when energized to separate said main contacts, a relay coil, contacts associated with said relay coil which when closed complete a shunt path across the terminals of said operating coil and which are adapted to be separated when said relay coil is energized by an overload current to interrupt said shunt path and thereby cause the overload current to be diverted through said operating coil to separate said main contacts, means for locking said main contacts in open relation after a pre 17 c determined number of opening and reclosing operations of said main contacts, means operable by said relay coil for delaying opening of said shunt contacts on energization of said relay coil by an overload current, means for normally rendering said delaying means inoperative and operated by said locking means to render said delaying means operative, and means actuated by said locking means for retarding reclosing operations of said main contacts.

4. An automatic reclosing circuit breaker comprising a plurality of main contacts, an operating coil having terminals and adapted when energized to separate said main contacts, a relay coil, contacts associated with said relay coil which when closed complete a shunt path across the terminals of said operating coil and which are adapted to be separated when said relay coil is energized by an overload current to interrupt said shunt path and thereby cause the overload current to be diverted through said operating coil to separate said main contacts, means for locking said main contacts in open relation after a predetermined number of opening and reclosing operations of said main contacts, means operable by said relay coil for delaying opening of said'shunt contacts on energization of said relay coil by an overload current, means normally rendering said delaying means inoperative and operated by said locking means closed complete a shunt path across the terminals of said operating coil and which are adapted to be separated when said relay coil is energized by an overload current to interrupt said shunt path and thereby cause the overload current to be diverted through said operating coil to separate said main contacts, means for locking said main contacts in open relation after a predetermined number of opening and reclosing operations of said main contacts, means operable by said relay coil for delaying opening of said shunt contacts on energization of said, relay coil by an overload current, means actuated by said locking means and cooperating with said delaying means in a manner to control operation of said delaying means, means actuated by said locking means for retarding reclosing operations of said main contacts, said means including an escapement mechanism, and means for locking said escapement mechanism during opening operations of said movable main contact.

6. An automatic reclosing circuit breaker comprising a plurality oi' main contacts, an operating coil having terminals and adapted when energized to separate said main contacts, a relay coil, contacts associated with said relay coil which when closed complete a shunt path across the terminals oi said operating coil and which are adapted to be separated when said relay coil is energized by an overload current to interrupt said shunt path and thereby cause the overload current to be diverted through said operating coil to separate said main contacts, means for locking said main contacts in open relation after a predetermined number oi' opening and reclosing operations of said maincontacts, means operable by said relay coil ior delaying opening oi said shunt contacts on energization of said relay coil by an overload current, means operated by said locking means forY retarding reclosing operations of said main contacts, said means including an escapement mechanism, and means actuated in response to actuation of said relay coil for locking said escapement mechanism during opening operations of said movable main contact.

7. An automatic reclosing circuit breaker comprising a plurality of main contacts, an operating coil having terminals and adapted when energized 'to separate said main contacts, a relay coil, contacts associated with said relay coil which when closed complete a shunt path across theA terminals of said operating coil and which are adapted to be separated when said relay coil is energized by an overload current to interrupt said shunt path and thereby cause the overload current to be diverted through said operating coil to separate said main contacts, means for locking said main contacts in open relation after a predetermined number of opening and reclosing operations of said main contacts, means operable by said relay coil for delaying openingof said shunt contacts on energization of said relay coilby an overload current, means operated by said locking means for retarding reclosing operations of said main contacts, said means including an escapement mechanism, and means comprising a springurged vpivotally supported element adapted to engage a part of said escapement mechanism in response to actuation of said relay coil for locking said escapement mechanism during opening operations of said movable main contact.

8. An automatic reclosing circuit breaker comprising a plurality of main contacts, an operating coil having terminals and adapted when energized to separate said main contacts, a relay coil, contacts associated with said relay coil which when closed complete a shuntpath across the terminals of said operating coil and which are adapted to be separated when said relay coil is energizedl by an overload current to interrupt said shunt path and thereby cause the overload current to be diverted through said operating coil to separate said main contacts, means for locking said main contacts in open relation after a predetermined number of opening and reclosing operations of said main contacts, means operable by said relay coil for delaying opening of said shunt contacts on energization of said relay coil by an overload current, and means actuated by said locking means and cooperating with said delaying means in a manner to control operation of said delaying means, said delaying means including` an inertia type time-delay mechanism c'omprising an assembly made up of gear wheels,

pinions, and a y wheel.

LROBERT A. GESELLSCHAP.

REFERENCES CITED UNITED STATES PATENTS Number Name Date 980,812 Meter et al Jan. 3, 1911 1,154,359 Basch Sept. 21, 1915 1,537,727 Anderson May 12, 1925 1,790,485 Ramey Jan. 27, 1931 2,069,082 Walle Jan. 26, 1937 2,210,669 Johnson Aug. 6, 1940 2,295,805 Palmer Sept. 15, 1942 2,333,604 Wallace Nov. 2, 1943 76 2,849,632 May May 23, 1944 

